M = Na, K, Rb, Cs - ACS Publications - American Chemical Society

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Calorimetric Investigation of PrBr3-MBr Liquid Mixtures (M = Na, K, Rb, Cs) L. Rycerz*,† and M. Gaune-Escard‡ †

Faculty of Chemistry, Department of Chemical Metallurgy, Wroclaw University of Technology, Wybrzeze Wyspianskiego 27, 50-370 Wroclaw, Poland ‡ Ecole Polytechnique, Mecanique Energetique, Technop^ole de Chateau-Gombert, 5 rue Enrico Fermi, 13453 Marseille Cedex 13, France ABSTRACT: The molar enthalpies of mixing (ΔmixHm) in liquid alkali bromide-praseodymium(III) bromide mixtures have been measured with a Calvet-type high temperature microcalorimeter over the entire composition range at 1070 K. All of the melts are characterized by negative enthalpies of mixing with a minimum value shifted toward the alkali bromide-rich compositions that are located in the vicinity of x(PrBr3) ∼0.4. The magnitude of the mixing enthalpy depends on the ionic radius of the alkali metal, radius of the common halide ion, and the ionic radius of the lanthanide(III) cation.

1. INTRODUCTION The present work is a continuation of our systematic research performed on PrBr3-based systems. Recently the phase diagrams of PrBr3-MBr (M = Li, Na, K, Rb, Cs) binary systems as well as thermodynamic functions of congruently melting M3PrBr6 compounds were determined.1
5 This work reports the results of mixing enthalpy measurements performed on PrBr3-MBr (M = Na, K, Rb, Cs) liquid systems over the whole composition range. All gathered experimental data were subsequently optimized by computer coupling of phase diagrams and thermochemistry (CALPHAD) method, as was done for analogous CeBr3-MBr binary systems.6

Table 1. Molar Enthalpies of Mixing ΔmixHm and Interaction Parameters λ of the PrBr3
NaBr Liquid System at T = 1070 K ΔmixHm x(PrBr3)

2. EXPERIMENTAL SECTION 2.1. Chemicals. Praseodymium(III) bromide was synthesized

from the praseodymium oxide, Pr6O11, by a method analogous to that used for CeBr3 synthesis.7 The main steps of the synthesis involve: dissolution of praseodymium oxide in hot concentrated hydrobromic acid, crystallization of PrBr3 3 xH2O hydrates, their dehydration in the presence of ammonium bromide, melting of anhydrous praseodymium bromide, and its distillation under reduced pressure (∼0.1 Pa) in a quartz ampule at 1150 K. PrBr3 prepared in this way was of a high purity—min. 99.9 %. Chemical analysis was performed by mercurimetric (bromine) and complexometric (praseodymium) methods. The results were as follows: Pr, (36.96 ( 0.15) % (37.02 % theoretical); Br, (63.04 ( 0.11) % (62.98 % theoretical). Sodium, potassium, rubidium, and cesium bromides were Merck Suprapur reagents (min. 99.9 %). Prior to use, they were progressively heated up to fusion under a gaseous HBr atmosphere. HBr in excess was then removed from the melt by argon bubbling. All chemicals were handled in an argon glovebox with a measured fraction of water of about 2 mg 3 kg
1 and continuous gas purification by forced recirculation through external molecular sieves. r 2011 American Chemical Society


1

kJ 3 mol

λ

ΔmixHm
1

kJ 3 mol

x(PrBr3)


1

kJ 3 mol

λ kJ 3 mol
1

0.026


0.825


32.578

0.477


5.054


20.259

0.044


1.113


26.459

0.528


4.751


19.063

0.099


2.543


28.509

0.590


4.522


18.693

0.152


3.406


26.424

0.649


4.071


17.871

0.199 0.249


4.214
4.906


26.437
26.235

0.704 0.750


3.421
2.858


16.417
15.243

0.284


5.017


24.672

0.792


2.476


15.030

0.324


5.423


24.759

0.823


2.146


14.732

0.375


5.435


23.189

0.884


1.537


14.989

0.430


5.452


22.243

0.923


1.017


14.310

2.2. Measurements. The mixing experiments were all of the simple liquid
liquid type, performed under pure argon at atmospheric pressure. The Calvet-type high-temperature microcalorimeter, the mixing device, and the “break-off bubble” experimental method have all been described in detail elsewhere.7,8 Calibration of the calorimeter was performed with R-Al2O3 (National Institute of Standards and Technology, NIST). A detailed description of the calorimeter constant determination, calibration of the thermocouple used to measure the experimental temperature, and discussion of errors that influence the results of the mixing enthalpy measurements was presented in our previous paper.7 The relative error of mixing enthalpy determination was estimated as ( (6 to 8) %.

Received: August 2, 2010 Accepted: June 14, 2011 Published: June 30, 2011 3273

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Table 2. Molar Enthalpies of Mixing ΔmixHm and Interaction Parameters λ of the PrBr3
KBr Liquid System at T = 1070 K ΔmixHm x(PrBr3)


1

kJ 3 mol

λ

ΔmixHm
1

kJ 3 mol

x(PrBr3)


1

kJ 3 mol

λ kJ 3 mol
1

0.052


2.811


56.611

0.542


11.713


47.194

0.100


5.957


66.188

0.611


10.645


44.799

0.155 0.187


9.077
10.128


69.413
66.700

0.659 0.692


10.063
9.174


44.805
43.042

0.240


11.825


64.793

0.744


7.349


38.584

0.297


12.830


61.497

0.789


5.452


32.749

0.343


13.004


57.697

0.843


4.124


31.159

0.399


13.312


55.513

0.898


2.925


31.933

0.454


12.704


51.249

0.947


1.725


34.368

0.490


13.278


53.131

Figure 1. Molar enthalpies of mixing ΔmixHm of the PrBr3-MBr liquid systems: O, NaBr; b, KBr; 4, RbBr; 2, CsBr.

Table 3. Molar Enthalpies of Mixing ΔmixHm and Interaction Parameters λ of the PrBr3
RbBr Liquid System at T = 1070 K ΔmixHm x(PrBr3)

kJ 3 mol
1

λ kJ 3 mol
1

ΔmixHm x(PrBr3)

kJ 3 mol
1

λ kJ 3 mol
1

0.032


2.379


76.801

0.514


15.628


62.561

0.054


4.196


82.139

0.554


14.002


56.660

0.073


5.691


84.098

0.606


13.158


55.109

0.101


7.273


80.101

0.653


11.543


50.942

0.121 0.152


9.314
11.384


87.571
88.319

0.682 0.725


10.746
8.518


49.549
42.723

0.181


13.147


88.687

0.757


7.765


42.212

0.200


14.368


89.803

0.791


6.619


40.038

0.251


15.783


83.952

0.837


4.775


34.999

0.301


16.809


79.891

0.875


4.747


43.401

0.353


17.118


74.950

0.915


2.660


34.201

0.404


16.976


70.503

0.956


1.758


41.793

0.467


16.031


64.404

Figure 2. Molar enthalpies of mixing ΔmixHm of the PrBr3-MBr (M = Na, K) and PrCl3-MCl (M = Na, K) liquid systems: O, PrBr3
NaBr; dotted line, PrCl3
NaCl; b, PrBr3
KBr; dashed line, PrCl3
KCl.

Table 4. Molar Enthalpies of Mixing ΔmixHm and Interaction Parameters λ of the PrBr3
CsBr Liquid System at T = 1070 K ΔmixHm x(PrBr3)

kJ 3 mol
1

λ kJ 3 mol
1

ΔmixHm x(PrBr3)

kJ 3 mol
1

λ kJ 3 mol
1

0.032


2.828


91.296

0.471


18.369


73.724

0.051


4.689


96.882

0.526


18.517


74.268

0.096


8.712


100.387

0.576


16.582


67.897

0.151


13.097


102.161

0.650


14.595


64.153

0.199 0.241


15.888
17.945


99.674
98.103

0.696 0.758


13.480
11.260


63.710
61.384

0.301


18.942


90.028

0.806


9.558


61.127

0.357


19.302


84.085

0.849


6.925


54.017

0.400


18.835


78.479

0.894


5.424


57.236

0.434


19.022


77.437

0.948


2.960


60.054

3. RESULTS AND DISCUSSION The calorimetric experiments were performed at 1070 K over the entire composition range for the systems with NaBr, KBr,

Figure 3. Molar enthalpies of mixing ΔmixHm of the PrBr3
KBr (b, solid line) and TbBr3
KBr 15 (dashed line) liquid systems.

RbBr, and CsBr. The results obtained are presented in Tables 1 to 4 and are plotted against composition in Figure 1. Three decimals (without physical meaning), in the presentation of thermodynamic values, are in accordance with the recommendation of the CODATA Task Group on Chemical Thermodynamic Tables.9 All of the melts are characterized by negative enthalpies of mixing with a minimum value of approximately (
5.4,
13.4, 3274

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ARTICLE

which is representative of the energetic asymmetry in these melts. The values of λ for the liquid systems under investigation are also included in Tables 1 to 4. For each system, the values of λ were fitted by the method of least-squares to a polynomial of the form λ ¼ A + Bx + Cx2 + Dx3 + Ex4

Figure 4. Variation of the interaction parameter λ with composition for the PrBr3-MBr liquid systems: O, NaBr; b, KBr; 4, RbBr; 2, CsBr.

Table 5. Least-Squares Coefficients for the λ Equation for Liquid Praseodymium(III) Bromide-Alkali Bromide Mixtures: λ (kJ 3 mol
1) = A + Bx + Cx2 + Dx3 + Ex4 and Standard Deviation (SE, in kJ 3 mol
1) system

A

B

C

D

E

SE

Pr
Na Pr
K


30.659
53.386

21.855
156.759


2.298 597.673


1.988
672.154

255.050

1.040 2.354

Pr
Rb


73.081


182.913

713.030


725.284

228.826

Pr
Cs


88.247


197.148

2.435

945.412


1237.810

523.766

2.112


17.1, and
19.3) kJ 3 mol
1, for M = Na, K, Rb, and Cs, respectively. Similarly, like in the case of CeBr3-MBr liquid mixtures,7 the minimum of the enthalpy of mixing is shifted toward the alkali bromide-rich compositions and is located in the vicinity of x(PrBr3) ∼0.4. The magnitude of the mixing enthalpy depends on the ionic radius of the alkali metal (Figure 1). The smaller the ionic radius, the smaller the absolute value of mixing enthalpy and the enthalpy minimum location shifted more toward the alkali bromiderich compositions. Accordingly, the absolute value of the mixing enthalpy is the largest for the system with CsBr and decreases in the sequence from CsBr to NaBr (as does ionic radius of M+). The mixing enthalpy also depends on the ionic radius of the common halide ion. As displayed in Figure 2, when this radius increases [from chloride to bromide, (181 and 196) pm, respectively10], a significant decrease of the mixing enthalpy is observed. For example, the minimum of the molar mixing enthalpy is of about
7.3 kJ 3 mol
1 and
17.1 kJ 3 mol
1 for the systems PrCl3
NaCl and PrCl3
KCl,11 whereas in analoguous PrBr3-based bromide systems these values are (
5.4 and
13.4) kJ 3 mol
1, respectively. Finally, the mixing enthalpy in LnX3-MX liquid systems is dependent on the ionic radius of lanthanide(III) cation. In Figure 3 the mixing enthalpy was plotted against molar fraction of the lanthanide halide for PrBr3
KBr and TbBr3
KBr.12 The decrease of the Ln3+ ionic radius from 101.3 pm (Pr3+) to 92.3 pm (Tb3+)10 results both in an increase of the absolute value of the mixing enthalpy, when compared to analogous alkali metal systems, and shifting of the mixing enthalpy minimum toward alkali halide-rich compositions. Figure 4 shows the composition dependence of the interaction parameter λ λ ¼ Δmix Hm =ðxðPrBr3 Þ 3 ð1
xðPrBr3 ÞÞÞ

where x is the mole fraction of PrBr3. The coefficients A, B, C, D, and E as well as the standard deviation (SE) are collected in Table 5. Figure 4 shows the dependence of the enthalpy interaction parameter λ on the mole fraction of PrBr3. All of the systems have negative interaction parameters λ, whose absolute values increase sharply with an increase of the ionic radius of the alkali metal cation. All systems show more negative values of the interaction parameter in the alkali bromide-rich than in the praseodymium bromide-rich range. The composition dependence of the interaction parameter λ for PrBr3-MBr systems is identical to the dependence observed for CeBr3-MBr systems7 and can be attributed to the formation of PrBr63
complexes in the melts. The possibility of octahedral LnX63
complex formation in LnX3-MX liquid mixtures was confirmed by Raman structural studies.13

4. SUMMARY The molar mixing enthalpies in the liquid praseodymium(III) bromide-alkali metal bromide systems have been measured over the whole composition range. All of the melts are characterized by negative enthalpies of mixing. The minimum of the enthalpy of mixing is shifted toward the alkali bromide-rich compositions and located in the vicinity of x(PrBr3) ∼0.4. The magnitude of the mixing enthalpy depends on the ionic radius of the alkali metal (the bigger radius the more negative the mixing enthalpy), the radius of the common halide ion (a significant decrease of the mixing enthalpy with an increase of this radius) and the ionic radius of the lanthanide(III) cation (a decrease of the Ln3+ ionic radius results both in an increase of the absolute value of the mixing enthalpy, when compared to analogous alkali metal systems and a shifting of the mixing enthalpy minimum toward alkali halide-rich compositions). The composition dependence of the interaction parameter λ for the PrBr3-MBr systems is indicative of PrBr63
octahedral complex formation. ’ AUTHOR INFORMATION Corresponding Author

*Tel.: +48 71 320 33 89. E-mail: [email protected]. Funding Sources

Financial support by the Polish Ministry of Science and Higher Education from budget on science in 2007
2010 under Grant No. N204 4098 33 is gratefully acknowledged.

’ ACKNOWLEDGMENT L.R. wishes to thank the Ecole Polytechnique de Marseille for hospitality and support during this work. ’ REFERENCES (1) Ingier-Stocka, E.; Rycerz, L.; Berkani, M.; Gaune-Escard, M. Thermodynamic and transport properties of the PrBr3
MBr Binary Systems (M = Li, Na). J. Mol. Liq. 2009, 148, 40–44. 3275

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(2) Rejek, J.; Rycerz, L.; Ingier-Stocka, E.; Gaune-Escard, M. Thermodynamic and Transport Properties of the PrBr3
KBr Binary System. J. Chem. Eng. Data 2010, 55, 1871–1875. (3) Rycerz, L.; Ingier-Stocka, E.; Berkani, M.; Gaune-Escard, M. Thermodynamic and transport properties of the PrBr3-RbBr binary system. J. Alloys Compd. 2010, 501, 269–274. (4) Rycerz, L.; Ingier-Stocka, E.; Berkani, M.; Gaune-Escard, M. Phase Diagram and Electrical Conductivity of the PrBr3-CsBr Binary System. Z. Naturforsch. 2010, 65a, 859–864. (5) Rycerz, L.; Chojnacka, I.; Berkani, M.; Gaune-Escard, M. Thermodynamic Functions of PrBr3 and Congruently Melting M3PrBr6 compounds (M = K, Rb, Cs). J. Chem. Eng. Data 2011, 56, 1293–1298. (6) Kapala, J.; Rutkowska, I.; Chojnacka, I.; Gaune-Escard, M. Modelling of the thermodynamic properties of the ABr-CeBr3 (A = Li-Cs) systems. CALPHAD: Comput. Coupling Phase Diagrams Thermochem. 2010, 34, 15–19. (7) Rycerz, L.; Gaune-Escard, M. Calorimetric investigation of the CeBr3-MBr liquid mixtures (M = Na, K, Rb, Cs). J. Chem. Eng. Data 2009, 54, 2622–2625. (8) Gaune-Escard, M. Thermochemical methods. In Molten Salts: From Fundamentals to Applications, NATO Science Series; Gaune-Escard, M., Ed.; Kluwer Academic Publishers: Norwell, MA, 2002; Vol. 52, p 375. (9) CODATA Thermodynamic Tables, Selection for Some Compounds of Calcium and Related Mixtures: A Prototype Set of Tables; Garvin, D., Parker, V. B., White, H. J., Eds.; Hempshire Publishing Corporation: Bristol, PA, 1987. (10) Sharpe, A. G. Inorganic Chemistry; Longman: New York, 1986. (11) Gaune-Escard, M.; Rycerz, L.; Szczepaniak, W.; Bogacz, A. Calorimetric investigation of PrCl3-NaCl and PrCl3-KCl liquid mixtures. Thermochim. Acta 1994, 236, 59–66. (12) Rycerz, L.; Gaune-Escard, M. Mixing enthalpies of TbBr3-MBr liquid mixtures (M = Li, Na, K, Rb, Cs). Z. Naturforsch. 2001, 56a, 859–864. (13) Photiadis, G. M.; Borresen, B.; Papatheodorou, G. N. Vibrational modes and structures of lanthanide halide-alkali halide binary melts: LnBr3-KBr (Ln = La, Nd, Gd) and NdCl3-ACl (A = Li, Na, K, Cs). J. Chem. Soc., Faraday Trans. 1998, 94 (17), 2605–2613.

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